Virtual communications assessment system in a multimedia environment

ABSTRACT

A system for data recording across a network includes a session border controller connecting incoming data from the network to an endpoint recorder. A load balancer is connected to the network between the session border controller and the endpoint and receives the incoming data from the session border controller, wherein the load balancer comprises computer memory and a processor configured to parse the incoming data into video data and audio data according to identification protocols accessible by the processor from the computer memory. A recording apparatus includes recording memory that receives the incoming data from the load balancer, stores a duplicate version of the incoming data in the recording memory, and connects the incoming data to the endpoint.

CROSS REFERENCE TO RELATED APPLICATIONS

This application claims priority to and incorporates entirely by reference U.S. Provisional Patent Application Ser. No. 62/393,601, filed on Sep. 12, 2016, and entitled “SYSTEM AND METHOD FOR PARSING AND ARCHIVING MULTIMEDIA DATA.”

This application claims priority to and incorporates entirely by reference U.S. Provisional Patent Application Ser. No. 62/393,605 filed on Sep. 12, 2016, and entitled “VIRTUAL COMMUNICATIONS IDENTIFICATION SYSTEM WITH INTEGRAL ARCHIVING PROTOCOL.”

This application claims priority to and incorporates entirely by reference U.S. Provisional Patent Application Ser. No. 62/393,607 filed on Sep. 12, 2016, and entitled “VIRTUAL COMMUNICATIONS ASSESSMENT IN A MULTIMEDIA ENVIRONMENT.”

BACKGROUND

A traditional passive tap recording technique includes recorders that are deployed along routes of communications. In this technique, each recorder operates similar to a “sniffer” by analysing pass-by communication packets. The recorder records the packets corresponding to certain communication sessions based on its configuration. FIG. 1 shows a typical deployment of passive tap recorders in a contact center. In an IP telephony environment, recorders are typically deployed either at the voice gateway, which interfaces between Internet Protocol (IP) network and public switched telephone network (PSTN), or at switches in order to stay along the routes of the communications. This technique has the advantages of (1) minimum intrusion to a communication system, (2) cost effectiveness in deployment for companies with centralized office locations, and (3) easy scalability for compliance recording. However, for companies with many distributed branch offices, the above advantages start to diminish. This is especially true if the purpose of the recorders is for quality monitoring.

First, with the growing usage of Voice over Internet Protocol (VoIP) technology, many telephony-based businesses, such as contact centers, are adopting distributed telephony systems with local access to PSTN, which are still controlled by centralized soft switches. Many contact centers are using at-home agents with soft-phones on their personal computers (PCs). The distributed telephony system makes “recording along the communication routes,” needed for passive tap recording, difficult. Secondly, network security has now become a concern. The deployment of encryption technology has made passive tap recording become even more problematic.

In addition, many contact centers deploy recorders for quality monitoring purpose, in addition to compliance. In this regard, only a small percentage of the communications are recorded and monitored. However, to assure the accuracy of the sampling, communications are randomly selected for recording across all branch offices. With passive tap recording, a large number of recorders will be required and each recorder will have very low usage.

A typical IP-based contact center using the passive tapping “sniffing” recording method is shown in FIG. 1 . Two branch offices are shown in the figure. To communicate with any agents at the contact center, a customer communication device, such as a time domain multiplexing (TDM) or an IP phone, first sends communication signals to a call-processing device of the contact center, such as a soft switch. The communication signals can be sent either directly to the call-processing device in case of IP to IP communications or via a media processing device, such as a voice gateway in case of TDM to IP. The communication network can be a PSTN network or IP-based network. Once the communication signals have been received, the call-processing device then routes the communication signals to an agent phone.

After several rounds of communication signals exchange, media communications between the agent's phone and customer's phone can proceed via media processing device and distribution devices. The distribution devices are network routers and switches. In order to record the media communications using passive tapping, recorders are deployed at the media processing device or distribution devices using the network traffic monitoring or duplicating features, such as the Cisco's Switch Port Analyzer (SPAN) feature, on these devices. These tapping features are often available to the recorders that are directly connected to the media processing device or distribution devices, namely to recorders deployed at each branch office. Hence, a large contact center having multiple branches, such as a branch in New York, a branch in Los Angeles, and a branch in Chicago, may need multiple recorders in each branch to record the media communications.

The above description of recording operations reaches yet another hurdle when video data is added to the mix. Techniques that were previously used in audio recording cannot immediately convert to handle audio data. This is particularly true in terms of storing long term audio and video data in a compressed state. For example, audio/voice data may be transmitted across a network in a native state at 64 kbps. Modern compression techniques, however, allow for that data to be stored with sufficient integrity at 5.3 kbps. The same is not true for video data, which may be transmitted at 4000 kbps and stored in ranges of 500 kbps. Screen data transmitted across a network has even greater compression requirements in which screen data transmitted at 4000 kbps may be stored at a rate of 5 kbps. Accordingly, new techniques for transmitting and storing both audio and video data in a network setting are necessary for modern file retention policies and government regulated procedures for storing data.

BRIEF SUMMARY OF THE DISCLOSURE

A system for data recording across a network includes a session border controller connecting incoming data from the network to an endpoint recorder. A load balancer is connected to the network between the session border controller and the endpoint and receives the incoming data from the session border controller, wherein the load balancer comprises computer memory and a processor configured to parse the incoming data into video data and audio data according to identification protocols accessible by the processor from the computer memory. A recording apparatus includes recording memory that receives the incoming data from the load balancer, stores a duplicate version of the incoming data in the recording memory, and connects the incoming data to the endpoint.

BRIEF DESCRIPTION OF THE FIGURES

FIG. 1 is a schematic diagram of an embodiment of a prior art system for passive tap recording in a multi-campus network.

FIG. 2A is a schematic diagram of an embodiment of a system in which multimedia communication at a company can be recorded by an endpoint recorder located anywhere on an IP network connected to the company.

FIG. 2B is a schematic diagram of an embodiment of a system in which hardware architecture transmits and receives multimedia data via local interfaces in a network.

FIG. 3A is a schematic diagram of an embodiment of a system in which media communication at a contact center can be recorded by a multimedia endpoint recorder located anywhere on an IP network connected to the contact center using a conference bridge.

FIG. 3B is a schematic diagram of an embodiment of a system in which customer-agent interactions along a computerized interface are directed to at least one multimedia recorder by tapping communications at the agent computer.

FIG. 4 is a schematic diagram of an embodiment of a system in which media communication at a contact center with multiple branch offices can be recorded by at least one multimedia endpoint recorder located anywhere on an IP network connected to the contact center using a conference bridge.

FIG. 5A is a schematic diagram of an embodiment of a system in which multimedia data is recorded across a network interface via a load balancer arrangement.

FIG. 5B is a schematic diagram of an embodiment of a system in which multimedia data is recorded across a network with strategically placed data taps connected to identified hardware at multiple locations.

FIG. 6A is a schematic diagram of an embodiment of a system in which multimedia data is recorded across a network by tapping a switch port analyzer.

FIG. 6B is a schematic diagram of an embodiment of a system in which multimedia data is recorded across a network by tapping the switch port analyzer of FIG. 6A.

FIG. 6C is a schematic diagram of an embodiment of a system in which multimedia data is recorded across a network via computer-telephony integration utilizing a real time information server.

FIG. 6D is a schematic diagram of an embodiment of a system in which multimedia data is recorded across a network by tapping a switch port analyzer and recording data in conjunction with computer-telephony integration utilizing a real-time information server.

FIG. 7 is a schematic diagram of an embodiment of a system in which recording operations are managed in conjunction with an internet protocol analyzer.

FIG. 8 is a flow diagram that illustrates an example of operation of a system such as shown in this disclosure.

FIG. 9 is a sequence diagram of an embodiment of a system in which multi-campus communications between agents and customers are recorded via a multimedia application server as described herein.

FIG. 10 is a flow chart of recording operations of a system shown in FIG. 9 .

FIG. 11 is a sequence diagram of an embodiment of a system in which a media communication can be recorded via a media application server.

DETAILED DESCRIPTION

Disclosed herein are systems and methods for recording multimedia communication signals without requiring recording devices to be deployed along the route of the two end points of the communication. In particular, the recording of the communication signals can be achieved using a soft switch, a conference bridge, a phone, a multi-media communication device, a computer having a CPU and camera/video capabilities and/or a media application server.

Exemplary systems are first discussed with reference to the figures. Although these systems are described in detail, they are provided for purposes of illustration only and various modifications are feasible. After the exemplary systems are described, examples of flow diagrams and sequence diagrams of the systems are provided to explain the manner in which communication signals can be recorded. This disclosure references numerous kinds of data for recording during normal business operations, and the data is not limited to any single protocol or payload content. References to multimedia data include, and are not limited to, text data, image data, audio/voice data, video data, computer screen data, live transmission, recorded transmission, still images, moving images, compressed audio, screen data, and video, and natively transmitted audio, screen data and video, just to name a few examples. This disclosure refers to a network and systems connected across network connections, which can include, without limitation, wired, wireless, optical, acoustic, or any other kind of data transmission protocol and medium. References to “phones” and similar terms are not limited to traditional voice processing telephones or even smart phones, but instead, this disclosure relates to all kinds of computer integrated telephony devices that enable audio, video, and interfaces for sharing data across a network.

Referring now in more detail to the figures, FIGS. 2A and 2B are schematic diagrams of an embodiment of a system in which media communication at a company can be recorded by an endpoint recorder located anywhere on an IP network connected to the company. Regarding FIG. 2A, two branch offices 203, 206 of a company may need to record communications between employees and between employees (or “agents”) and customers. Customer communication devices 223, 236 connect to branch offices 203, 206 either via an IP network 219 or via a PSTN network 216, 233, respectively. The customer communication devices 223, 236 can include, but are not limited to, telephones, soft-phones on hand held devices, personal computers, or any computerized device or system capable of retrieving, processing, and transmitting multimedia data across a network.

Recording device(s) 226 can be deployed anywhere on the IP network 219 connected to the branch offices 203, 206. Alternatively or additionally, the recording devices 226 can communicate with media controlling/processing/distributing devices 213, 231 in a secure fashion in encrypted environments, for getting communication events and for sending instructions. With the capability of the recording devices 226 to communicate with the media controlling/processing/distributing devices 213, 231, the recording device 226 can selectively record communications in the contact center based on business policy. Alternatively or additionally, if a recording device is a cluster of recording devices, the recording device can communicate with the media controlling/processing/distributing devices 213, 231 to select which recording device from the cluster of recording devices to record the communications for load balancing purposes.

The media controlling/processing devices control the communication between customers and employees and between employees. The media controlling/processing devices can include, but are not limited to, multimedia gateways, soft switches, conference bridges, and multi-media application servers. The distributing devices can include, but are not limited to, routers and switches. Based on static configuration or instructions from the recording devices, the media controlling/processing devices can duplicate and transmit on-going communication between communication devices 209, 229, 223, 236 to the recording devices via the IP network 219 using its multimedia processing features. Alternatively or additionally, the media controlling/processing devices can also instruct a communication device 209, 229 at the company premises 203, 206, respectively, to duplicate and transmit any on-going communications to the recording devices 226 using media processing features on the communication devices 209, 229. The operation of the system 200 is further described in relation to FIG. 8 .

FIG. 3 is a schematic diagram of an embodiment of a system in which multimedia communication at a contact center can be recorded by an endpoint recorder located anywhere on an IP network connected to the contact center using a conference bridge. The endpoint recorder is configured for receiving, processing, and storing all kinds of multimedia data, with examples shown in the figures as audio/voice, video, and screen shots or screen scraping data. As indicated in this figure, the system 300 comprises a contact center premises 301 that includes an IP telephony system 303 that enables communications between agent phones 319, 323, 326 and between agent phones and customer phone(s) 329. Use of the term “phones” includes all types and configurations of computerized devices operating as communication devices, including but not limited to computers fitted with two way live communication cameras and computer implemented telephony. The IP telephony system 303 includes soft switch 306, conference bridge 309, voice gateway 313 and agent phones 319, 323, 326, all of which are connected to a company network 316. Calls from the customer phone 329 can be routed to a voice gateway 313, which can route the calls to the soft switch 306. The soft switch 306 receives incoming calls and routes the calls to the agent phones 319, 323, 326. The soft switch 306 communicates with the conference bridge 309 via the company network 316. The IP telephony system 303 communicates with a voice endpoint recorder 339 via an IP network 333. The company network 316 and IP network 333 can include, but are not limited to, a wide area network (WAN), a local area network (LAN), a virtual private network (VPN) and the Internet.

In this embodiment, the soft switch 306 is operative to send a command to the agent phones 319, 323, 326 and voice gateway 306 via the company network 316, instructing the agent phones 319, 323, 326 and voice gateway 306 to transmit media communications associated with the incoming calls through the conference bridge 309 via the company network 316. The soft switch 306 also sends a command to the conference bridge 309 via the company network 316 to duplicate and transmit the media communication to the voice endpoint recorder 339 using the IP network 333. The operation of the system 300 is further described in relation to FIGS. 8 and 9 .

Alternatively or additionally, the soft switch can receive instructions for recording the media communication from the voice endpoint recorder 339 via the IP network 333. In turn, the soft switch sends a command based on the received instructions to the conference bridge 309. Alternatively or additionally, the soft switch 306 can have capabilities of a conference bridge. That is, the soft switch 306 can duplicate and transmit the media communication to the voice endpoint recorder 339 without using the conference bridge 309.

FIG. 4 is a schematic diagram of an embodiment of a system in which media communication at a contact center with multiple branch offices can be recorded by a voice endpoint recorder located anywhere on an IP network connecting to the contact center using a conference bridge. System 400 is similar to the system 300 in FIG. 3 described above. That is, the system 400 includes a contact center premises 401, customer phone 429, company network 416, multimedia data gateway 413, IP network 433, soft switch 406, agent computers and phones 419, 423, 426 and endpoint recorder 439.

As shown in FIG. 4 , the contact center premises 401 further include headquarters 403 that communicates with branches 443, 446 via the IP network 433. The headquarters 403 can be provided at one location, e.g., Chicago, and the branches 443, 446 can be provided at different locations, e.g., Los Angeles and Washington, D.C. Despite the different locations of the headquarters 403 and branches 443, 446, a multimedia communication can be recorded to a single multimedia endpoint recorder 439 using the conference bridge 409 and IP network 433. Note that the headquarters 403 includes a similar system as shown in FIG. 3 . That is, the headquarters 403 includes soft switch 406, conference bridge 409, company network 416 and agent multimedia computerized communication devices 419, 423, 426.

Agent multimedia communication devices 449, 453 within the branches 443, 446 can receive media communications from within the contact center premises 403 or from customer phones and customer multimedia communication devices 429. The soft switch 406 can send a command to the agent devices 449, 453 instructing the agent devices 449, 453 to transmit media communication through the conference bridge 409 via the IP network 433. The soft switch 406 also can send a command to the conference bridge 409 via the company network 416 to and transmit the media communication associated with the agent phones 449, 453 to the voice endpoint recorder 439 using the IP network 433. The operation of the system 400 will also be described in greater detail in relation to FIGS. 8 and 9 .

FIG. 8 is a flow diagram that illustrates an example of operation of a system such as shown in FIG. 2 . Beginning with block 802, communication signals are received in a contact center. In block 803, the contact center determines whether to duplicate the communication signals such as such as by using the media controlling/processing/distributing devices 213, 231, as shown in FIG. 2 . Alternatively or additionally, a recording device can provide instructions to the media controlling/processing/distributing devices 213, 231 for recording the communication signals. In block 804, the contact center duplicates the communication signals such as by using the media controlling/processing/distributing devices 213, 231 or communication devices 209, 229. In block 805, the duplicated communication signals are transmitted to an endpoint recorder using a network. In block 806, the end point recorder records the duplicated communication signals.

As used herein, data gathered and recorded pursuant to the embodiments of this disclosure may incorporate audio, video, text, screen data or other data types as necessary to effect the purposes of this disclosure. Also, these systems are configurable for use with visual communication mechanisms, such as a sign language system using video data that may circumvent detection of communication via audio or text channels. Other data that may be gathered for analysis pursuant to the embodiments herein include the number, age, gender of people subject to video, audio, text, or other data communications discussed herein.

Session Boarder Controllers (SBC), Load Balancers (LB), and Gateways (GW) are present in some systems such that the multimedia audio, video, text, and/or screen data (or the like) will be streamed to a multimedia data recorder from the session border controller, or the video gateway. The multimedia data may also be streamed to a recording location from a multimedia processing server that is dealing with conferencing and compression services in the multimedia communication stream. In one embodiment, the system may utilize a session border controller with a data recorder inside for video/audio recording; this allows for using the session border controller to off load trans-coding functions to the lowest possible storage rate. All systems described herein also make use of forking capabilities, SIP recording, and correlating a call from a traditional telephone switch to a recipient for recording through a voice over IP switch.

The use of a load balancer is also set forth herein, since video recording will initially be done using passive interception of the video communication, and the network traffic increases with video, there is likely a need to leverage load balancing technology to distribute the traffic intelligently across the cluster of recorders increases. Intelligent distribution of multimedia audio/video traffic includes enabling the load balancer to distinguish audio and video components. Heuristic analysis is necessary to incorporate identification protocols into a load balancer; a rules based analysis can be used to identify video and keep audio/video appropriately paired for arrival at destination.

The video and audio portions of a call are covered as well as the fact that the video and audio portions go to the same recorder or different recorders and that the recorders have the logic to associate the streams together. This disclosure explains the use of other call information from the control protocol such as SIP or from a computer telephony integration (“CTI”) type interface to gather appropriate data to associate matching audio and video data streams.

Also this disclosure incorporates the scenario where the load balancer does not exist between the session border controller and the multimedia recorder, for example one typical deployment might be a session border controller communicating with a Recorder Control Server, and this determines recorders with free capacity or recorders closest to the session border controller. The recording control server may utilized on-the-fly live adjustments to direct recording operations or other routing algorithms that instruct the session border controller to forward the multimedia packets, such as text, screen data, audio or video to the server. In this case there is not a load balancer that the media streams are passing through.

One method and associated system may utilize a Duplication Media Streaming (DMS) protocol to support the streaming of the video directly to the recorders. Other embodiments described herein record incoming data in real time and directly stream the incoming data to an endpoint.

A system for data recording across a network then may include a session border controller connecting incoming data from the network to an endpoint. A load balancer connected to the network between the session border controller and the endpoint receives the incoming data from the session border controller. The load balancer comprises computer memory and a processor configured to parse the incoming data into respective screen data, video data and/or audio data according to identification protocols accessible by the processor from a computerized memory. A recording apparatus including recording memory receives the incoming data from the load balancer, stores a duplicate version of the incoming data in the recording memory, and connects the incoming data to the endpoint. The identification protocols utilize heuristic analysis of meta data that identifies portions of the incoming data. The heuristic analysis determines a data identifier selected from a file type, a data type, or a compression protocol for at least one portion of the incoming data. In one non-limiting example, the data identifier represents that the portion of the incoming data is a WAV file, an XML file, an SCN file, an FLV file, a WMV file or an MP4 file.

In one embodiment, a processor of the load balancer parses identified portions for forking transmission of the respective portions according to a data identifier transmitted with the data stream. A data identifier may be a file type, certain objective meta data, a portion of a data stream header, or even an attribute of a data stream payload. A system of this embodiment utilizes the identified portions as are stored in respective sections of the recording memory according to the data identifier for each portion. The identification protocols used to process incoming multimedia data are stored in the memory for access by the processor as respective real time analytics modules and are subject to call for incoming data. The incoming data may originate from a first private branch exchange or any video management system connected to a subject network and may be directed to at least one session border controller that may be positioned proximate a second private branch exchange remote from the first private branch exchange.

In another embodiment, a system as described herein further includes a session border controller housing encompassing the recording apparatus and the load balancer. A video processing server receives the incoming data from the first private branch exchange and transmits the incoming data stream to the session border controller in the second private branch exchange.

A recording apparatus in the data path, and possibly housed within the session border controller is configured for recording. The session border controller includes a session border controller processor configured for transcoding the incoming data according to audio or video data type.

The session border controller may further include a back to hack agent module accessible by the processor for moderating the incoming data to the endpoint. In regard to a video back to back agent, the method and system of this disclosure includes a video solution incorporating hardware as a proxy for the video i.e., it is routed through identified hardware to a data recorder. The back to back video transmission device is the intermediary agent/recorder and a switch administrator programs the video back to back agent for proper security access to record.

In another embodiment, unique topologies available on or in system hardware and software configurations optimise the environment for large and widely distributed customers over variable geographic distances. This embodiment confers an ability to record full time audio with selective video and selective screen capture, and any combination of these being full time or selective recording. This is where, subject to configuration or rules programmed into either a server, session border controller, recorder, or other hardware, the decision to record any of the elements beyond audio is made selectively. This might be due to a randomising rule, a line of business rule, or 3^(rd) party tagging of the data. As discussed above, tagging may be incorporated via a data stream header or metadata transmission with multimedia data files. Options for using the time stamp on video/audio data and rebuilding the proper content at a remote location and taking drift across different systems into account.

The systems described herein are configured in computerized software with an ability to record audio, video and screen on the same computer implemented machine or different machines. This decision can be made intelligently based on topological information. For example, screen data displayed at either or both of customer and agent locales may be recorded local to the agent site, whereas the audio and video may be recorded in the data centre since the traffic already flows through there. The hardware described herein, such as endpoint multimedia recorders, include an ability not only to record on different machines but also, at the time of replay, to rebuild the content from the different recorders for replay.

Video may be recorded on a different recorder to its audio due to differences in retention and storage requirements. Audio may be kept for life of a retention policy, whereas there may be no requirement to store the video long term and, therefore, video data, which requires a larger amount of storage memory, may be allowed to just roll off the buffer. Equally, the audio, video and screen data may all have different retention policies which are subject to rules driven by configuration and rules which may determine recording times based on the above described tagging of files or associated metadata. The tagging on files related to a call or multimedia agent-customer interaction may include information such as agent identification, extension numbers, customer account numbers, DNIS, ANI, CLI or any other tagged data in the multimedia data streams. In one point of consideration, tagging content in video/audio/screen data storage may be examined and utilized along numerous points in a recording process. This tagging may instruct hardware, via computer implemented machine instructions, to implement a recording system with: (a) down sampling for long term storage (b) consideration international laws on kinds of screen/audio/video required to be secured in all circumstances such as ATM transactions; (c) desktop applications, kiosk applications and particular hardware/algorithms implicated in each.

The use of topology information can be used to determine which of the multimedia streams relates to the agent and which of the multimedia streams relates to the customer. This will be important for optimising performance in the use of face recognition, in order to only carry out the comparison on the data stream with an external party where required, subject to configuration. The topology information may also be used to determine the emotions and other derived data from the video footage of video and audio data, corresponding to a customer at one work station or computer vs. the agent at another. Where conferences are involved video topology will be used to determine which stream to do multiple matches on vs the agent side.

The data transmissions discussed herein also use metadata analysis for fraud scoring of video/audio/screen capture; same for quality scoring and use of quality data to initiate other processes such as video image recognition. When dealing with conferences of high definition video recording, the multimedia data gathered according to this disclosure records multiple time entries for each participating agent in a multimedia conference. These multiple transmissions may become an issue, therefore, so the system will have the ability to determine, during multiple internal party conferences, to store certain kinds of multimedia data, e.g., the video data, on one channel but correlate the data to multiple parties. Such correlation thereby optimises storage with the use of de-duplication of the video recordings by comparing time data among numerously transmitted multimedia data files.

In another embodiment, analysis of recorded data for payment card industry compliance may be used to identify certain regions and components of the computerized multimedia screen display and use data processing techniques to obscure (i.e., black out) certain multimedia data on a pixel by pixel basis. This process may further utilize text box identification in recorded data streams to allow for retroactive removal of certain portions of text, video and screen data that might not be suitable for storage or transmission outside of a single transaction. For instance, use of video/screen data for recording signed documents and identifying the document later from storage in a search tool does not necessarily entail recording and storing all of the multimedia data available in a transaction. This system, therefore, uses down-sampling for long term storage after analytic processes are completed on multimedia data feeds and the system is configured to customize both the transmitted feed as well as the stored version. Accordingly, there are avenues available to give users the option of selecting among video call participants for recording. For example, the system may be configured for selecting one of several formatted call participants for recording, such as only one of an array of multimedia call participants. This example utilizes the concept that in many multimedia environments multiple participants can see every other participant, chosen participant, or just a subset of participants on respective computer screens (i.e., the screens of a multimedia transaction arrange particular video data in an arrangement that some might compare to the historical game show, Hollywood Squares or to the opening credit of The Brady Bunch on network TV where participants are arranged in an array. Proper storage and recording decisions in this arrangement could include gathering all of the participant data streams, some of the participant data streams, or maybe even just one of the multimedia data streams at issue. In other words, a call management and recording system according to this disclosure may make decisions, via artificial intelligence and heuristic analyses, based on decision data for each participant data stream that includes, but is not limited to, the above noted time stamps, tags, quality measurements, meta data, or even by using the delta signals of a gathered video/audio/screen sample. Decision protocols, programmed in computer implemented memory, will record certain components of interest according to a combination of the above described decision data. One goal is to have appropriate recording algorithms available for disparate multimedia data that are ultimately useful only if tied together via appropriate logic for recreating the gist of the interactions from a recorded and stored version, that may or may not include all of the participant data.

In order to improve the performance of the endpoint recorders not limited to video, but of particular value when considering video, certain embodiments of this disclosure utilize the ability to offload processor intensive work to one or more graphical processing units (“GPUs”), either co-resident in the machine doing the multimedia recording or in the recording system where a bank of GPU's is made available to provide processor services to the recorders. In this embodiment, the session border controller and/or the load balancer would likely be able to offload to a GPU certain activities such as format conversion and compression, particularly when considering the storage requirements for video; therefore, it will become important to compress to as small of a format as possible. It is envisaged the recorder will seamlessly use the GPU's both in real time compression activities and post process activities. In order to optimise the storage of the video, it may also be converted into a series of stills that are played like a flipbook, again with the purpose of saving storage. This might be done in real-time or at the point of long term storage.

Some goals of these embodiments described in this disclosure include maximizing the use of GPUs and application specific integrated circuits “ASICs” in the right context. These kinds of processes include proper offloading of processor intensive data manipulation, exploring the options and algorithms available for hand-off processing between CPU and GPU, assigning CPU reconstruction duties of a frame from video stream of delta signal and snapshots; decoding of picture frames to GPU; capturing desktop screen on CPU; and developing algorithms for assigning tasks properly between CPU and GPU. Other algorithms possible here include developing a scoring agent on a CPU such as quality of eye contact, eye movement, and smile quality. Data processing offloading algorithms further allow for intelligently selecting the appropriate hardware for particular tasks, such as using the GPU to decode (rapidly) certain triggers and scores and selectively moving processes to GPU, CPU, ASICs to enable. e.g., branch recording at a remote screen and putting proper analytics package in place that can implement video/audio/screen processing most effectively in a particular topology.

In one embodiment then, a system for data recording across a network (500) includes incoming data from the network to an endpoint set of recorders (515A-5150) and a load balancer 514. In the embodiment of FIG. 5A, therefore, one schematic delineates the network segment (500) of a multimedia conferencing process to a client segment (550) of that process, such as client equipment distributed across different campuses of an organization. The data flow of this embodiment connects multimedia network data to at least one of a gateway (509A) and a session border controller (513A) and the endpoint recorders (515). The example of FIG. 5A illustrates a multimedia data recording operation by which a redundant data gateway arrangement (509A, 509B) provide fail-over operations to allow for respective data recording and storage (515A-D and 515E-G). The load balancer (514A) receives the incoming data from the session border controller or gateway configuration. The load balancer (514A), therefore, includes computer memory and a processor configured to parse the incoming data into data types, such as screen data, video data and audio data according to identification protocols available to the processor. The system further incorporates a recording apparatus (515) comprising an archiving processor and archiving memory that receives a duplicate version of the incoming data from the load balancer and stores the duplicate version of the incoming data in the recording memory. At least one graphics processing unit (GPU) and at least one application specific integrated circuit (ASIC) may be connected to the recording apparatus, wherein the recording apparatus comprises an archiving module stored in said archiving memory, the archiving module configured to use the archiving processor to process portions of the duplicate version of the incoming data along with either the GPU or the ASIC. The gateway or session border controller creates the duplicate version and directs the incoming data to the endpoint via the load balancer. The GPU is used for format conversion, image decoding, and compression. The GPU is configured to process the portions of the duplicate version into image stills for storage. The archiving processor and ASIC are configured to construct frames of the duplicate version. Finally, the session border controller is configured as an SIP proxy for incoming data.

FIG. 5B incorporates more strategic recording and storage options for the multimedia data described above. In the embodiment of FIG. 5B, the recording operations are strategically handled by intelligent and automated protocols for determining a tap location for the data to be directed to a recorder. In a data recording and storage operation, not only can the hardware such as a gateway, session border controller, or load balancer (and the duplicate versions thereof) apply logical operations on multimedia data, but an overall multimedia server may be implemented to manage tap locations that are available in the overall network. In this regard, a given network configuration may have at its disposal proper installations of recording equipment configured to tap, or access and direct, multimedia data at critical points in the architecture. As used herein, therefore, a tap is a hardware installation at strategic points in a network that a recording operation can locate, intelligently select, and command operation of data retrieval of multimedia data in a native format. FIG. 5B illustrates a tapping operation at tap points for a network tap (T_(NW)) (513A), a session border controller tap (T_(SBC)) (513B), a gateway tap (T_(GW)) (513C), or a tap for a switch port analyzer (T_(SPAN)) (513D). Appropriately configured computer readable and executable software may be used in conjunction with the appropriate hardware to determine which tap location is appropriate for a given scenario and kind of data. In multiple stream data sets, the logic used in the network monitoring and implementation may select a tap location that is the same for or different for any given set of data streams, even if all of the data streams are directly related to a single transaction. The above noted tags in a plurality of data streams may be utilized to access and assign a tapping point across with a given data stream crosses. As illustrated in the figures, each tapping point, “T”, may be associated with, or assigned on an ad-hoc basis, a particular end point recorder (515) available on the network. Again, the assignments of a tapping point and a recorder, as well as the recording and storage format, may be made via heuristic analysis or artificial intelligence.

In one embodiment illustrated in FIG. 6A, the network hardware encompasses at least one location for storing computer implemented software that automatically and selectively directs hardware components to be an active tap site for a particularly identified stream of multimedia data. In the example of FIG. 6A, one tap site of interest may be a switch port analyzer, denoted by its commonly used acronym “SPAN.” The switch port analyzer of FIG. 6A is positioned as an integral component of the communications between an automated call distribution center having a private branch exchange (PBX) or IP-PBX. The recorder (617) may be particularly assigned in this embodiment to operations directing multimedia data streams to the recorder for storage and retention operations.

FIGS. 6B-6D provide numerous details of various configurations by which a single piece of hardware, for example only, the switch port analyzer may be a decisive point in assigning a multimedia data stream a destination or a portion of a network route, such as which load balancing operation (614) to use or which endpoint recorder (515) to be assigned. FIG. 6C utilizes the switch port analyzer (611) in connection with the private branch exchange automatic call distribution software (612) to direct at least one of a multitude of data streams to a real time information server (RIS) configured for use with modern and smart computer telephony integration.

The embodiment of FIG. 6D illustrates more detail of how the SPAN (611) is configurable with multiple data streams (1-8) on each port that, in one embodiment, is a multimedia stream directed to an agent from a customer via the gateway (609) and call manager (613). The last port shown (port number 8) consolidates all of the streams and directs the same to the real time information server (645) for processing and possibly either direct assignment to a recorder or further analysis via a load balancer for heuristics and recording assignments.

FIG. 7 illustrates yet another option in determining a network route, data format, compression state, recorder assignment, and tap point location for multimedia streams of data. The embodiment of FIG. 7 , shown with duplicate hardware (A, B) for failsafe operation, further incorporates an interact protocol analyzer (“IPA”). The IPA may be configured to work with associated computerized machines to identify data streams that should be paired for long term storage. This kind of pairing requires in depth consideration of the kinds of data, the data tagging, the signalling information, and the like for ultimately assigning a recording device.

One non-limiting goal of the embodiments of this disclosure include is that of recording multimedia data with the goal of eventually synchronizing component parts of a given transaction for record keeping and retention purposes. Pairing the data appropriate, regardless of which network route or hardware the data passes through, is important because if, for example, audio data and video data are “off” synchronized by as much as one tenth of a second, the delay is noticeable to the human brain. Also, some of these kinds of delay may be cumulative in certain configurations and must be accounted for in the recording operations.

While it may be desirable for components of a given multimedia communication session or transaction to follow the same network route, utilize the same hardware, and end up for recording at the same location, such precisely identical data management scenarios are often not possible. Recording systems, therefore, often must pair screen data, audio data, and video data according to know procedures by using the above described tagging operations as well as meta data and operational data gathered by various components of the network. In some instances, the signalling components of a data stream may be sufficient to provide information about a data set or a multimedia file so that it may be paired with related constituent parts of a communication session. In other operations, however, hardware along the network, such as the load balancer, gateway, session border controller, and the like may need to be configured for certain analytical procedures. Again, one goal of the comprehensive network architecture is not only to handle bi-directional communication during a transaction or communication session, but also to record the bi-directional communication in an optimal manner, considering variables such as retention time, compression states, and locations for tapping and recording. These kinds of procedures assist in not only providing a multimedia communications session in which data drifting out of synchronization is prevented but also the data is recorded in a way that allows for playback with network parameters taken into account.

FIGS. 9 and 10 collectively illustrate at least one exemplary embodiment of the system described herein allows for proper recording and storage of data related to agent and customer interaction in a commercial environment. In this example scenario, a customer walks into a branch, is initially picked up by the CCTV cameras such as but not limited to security cameras (1040), and the customer proceeds to the video kiosk where they then speak, via video link to an agent in a contact center. The same kind of environmental camera (1050) may be present on the agent operation side of the transaction so that various wide view perspective data may be gathered. Once the conversation has ended the customer then leaves the kiosk and is again picked by the CCTV. The customer's progression across the premises may include briefly speaking to another member of staff in the branch before leaving. In this scenario all video from the engagement will be linked and presented as a single instance of a contact with the agent. In other words, when a stored recording of the video and/or audio associated with this customer is replayed, the stored version can begin with the CCTV, then the Video and Audio Recording, then finishing with the CCTV in seamless fashion. This ability to link communication across different video cameras and indeed video channels allows various levels of branch or local analytics to take place, focused around how people interact and utilise the branch environment. A “stitched” camera perspective, therefore, is used to build a video journal of the customer's interaction with the business. The customer's interaction and data record stored in archival is not restricted it to just internal CCTV cameras. There may be others on the journey such as cameras in the ATM machine outside, mobile devices such as phones and tablets, body cams, video enabled glasses etc.

The video cameras that capture the customer and agent in a conversation may include be non-associated cameras in operation that are captured to assist with training. Without limiting the invention, and as an example only, a non-associated camera may be any recording device that is not directly involved in the enablement of the communication between the parties such as an agent and the customer. The non-associated camera, or any cameras discussed herein may be video and audio enabled or have only one of the two. For example a separate camera may be positioned to look at the agent to enable the analytics of how agents work when engaged in a customer interaction, such as body language etc. and this may require multiple perspectives of the agent and also provide visibility of off screen activities that potentially distract the agent.

In this regard, a recording system includes at least one agent computer configured to accommodate bi-directional communications over a network between the at least one agent computer and a remote computer, the at least one agent computer connected to a processor and memory configured with an archiving selection module. A first recording apparatus is in data communication over the network with the at least one agent computer, the first recording apparatus configured to implement instructions received from the archiving selection module to (i) selectively gather screen captures of the at least one agent computer during the bi-directional communications and store the screen captures with a respective time stamp; (ii) selectively gather video data generated at the at least one agent computer and store the video data with a video time stamp; and (iii) selectively gather audio data generated at the at least one agent computer and store the audio data with an audio time stamp. In another embodiment, the system may gather text data for situations such as agent-customer interactions via text chat. The archiving selection module comprises computer implemented commands stored therein to effect the selective gathering according to a randomizing rule, a line of business rule, or by locating a third party tag within the bi-directional communications. Data may further be gathered from data on the device or through integration with other applications. The system may optionally include an archival system connected to the network for storing the screen captures, the video data, and the audio data after assembling a consolidated communication according to the time stamps as adjusted for drift errors. In one embodiment, the first recording apparatus is positioned in a first private branch exchange local to the at least one agent computer, the system further comprising a second recorder in data communication with a customer computer in a second private branch exchange, the second recorder selectively gathering remote audio, remote video, and remote screen captures from the customer computer according to corresponding instructions from the archiving selection module. The archiving selection module is stored in a data center between the at least one agent computer and the customer computer. At least one agent computer is in communication with a load balancer comprising computer memory and a processor configured to parse the bi-directional communications into screen data, video data and audio data according to identification protocols accessible to the processor.

To ensure proper allocation of resources, the first recorder includes a respective portion of memory in the first recorder for audio data, video data, and screen capture data. In another embodiment, the system may utilize respective recorders for audio data, video data, and screen capture data. An archival system is connected to the network for storing the screen captures, the video data, and the audio data after assembling a consolidated communication according to the time stamps in the data, as adjusted for drift errors. An archival system comprises a consolidation module to pair audio data and screen capture data and store video data separately. A system according to embodiments herein operate according to rules based commands for down sampling for long term storage an incoming data stream according to content of audio data, video data, and screen capture data.

In order to allow increasing levels of Quality Assessment and Compliance, that the following information will be derived from the video streams in both real-time and post process analytics as part of the recording system:

-   -   Eye Contact between the parties involved in the video         interaction.     -   Stress levels detected from visual cues in the interaction.     -   Branding and position within the video interaction, is the         corporate branding conforming to standards and regulation.     -   Signals and signage use parties involved in the video         interaction, examples might be providing addition information to         influence a sale by showing someone on paper.     -   Gender detection     -   Emotion detection.     -   Obscured face detection.     -   Face detection, both of the customer and the agent, the agent         will be particularly important for remote agents to confirm the         correct person is on the video link.     -   In addition to face recognition other forms of authentication         may be used including deep vain, and retina scanning.     -   People counting, number of people involved in the interaction,         ensure people are not walking by the agent in the background for         example.     -   Minor detection if there are minors in the call that should not         be in a video call, this will trigger the stopping of video         recording.     -   Health condition cues such as excessive coughing may flag up to         health care providers and influence the assistance they provide,         another example my by pigmentation of the skin to detect medical         conditions.     -   GPS and location information, i.e. GPS location information of         the camera, but also location information such as angle and         orientation of the camera.     -   Flesh detection, agents and customers may requirement protection         from other parties on the call and detection of flesh and body         parts may form part of this protection and proactive alerting.     -   Video energy, the speed of change in the video screen may be         measured and used to drive a pictorial representation of the         video portion of the call, this activity displayed at replay         time would enable the replayer to jump to the area of high         video.

These analytics events will be combined with other data from the audio stream along with 3^(rd) party meta data to drive analyses. These analysis events, in turn, may drive email alerts, screen pops at the agent, supervisor or fraud advisors, desktop or mobile devices, or updates to 3^(rd) party applications. They may equally drive predictive analytics which in real-time will influence the scripts used in the call or any further routing that takes place within the call centre. Thus, video events will also be used to help contribute the quality assurance aspects of an agent/customer call where agents are automatically scored for engagement via virtual eye detection, brand representation, emotional responsiveness, etc.

The recording apparatuses and associated systems described herein account for passive versus active authentication. For example, software may be implemented using audio only to passively identify call participant without the participant even noticing or taking any particular step in the process. In active identification processes, the participant takes an affirmative step such as peering into a camera for eye detection. Assign active ID steps for legally required contexts such as detecting the age or status as a minor in a transaction.

At least one video camera is potentially always on in these embodiments, such that the potential for pre-video call analytics and actions are prevalent. For example, the recorder on seeing a person enter the kiosk could determine a high likelihood of their identity and allow the agent to great them immediately on connection. Alternatively it could route them to their preferred agent or one they have previously interacted with to provide that branch experience even in the kiosk. It might detect that they have a bike helmet on and ask them to remove this prior to connection. This system would likely use motion detection to identify someone in front of the camera at which point the recorder will invoke its pre-call video analytics and potentially influence the environment conditions at the camera by playing audio etc. The system may routing influence or indeed routing to a designated agent. Also the pre-identification of the customer at the kiosk could be used to influence delivery of adverts or other material to them while they are waiting for connection to the agent.

In certain embodiments, a pause/resume algorithm may apply to the video and/or audio recording to ensure that the system complies with payment card interfaces. These protocols allow for automatic stops during certain kinds of data recording, such as a credit card security “CV2” number collection. The system is configured via computer implemented software to recognize the collection of this data via word analysis or other techniques to pause recording for privacy issues. Upon completion of the data collection in real time by an agent, the recording system may implement a command to begin, or resume, recording again. Equally important other business requirements may require the selective pausing of the audio and not the video or any combination thereof. All recording operations discussed herein may account for features that are used during an interaction in a live multimedia interaction as shown in FIG. 9 . For example, the recording algorithms account for DPA Pause Events on desktop->Recording System Receives->pauses the Audio and Video Recording which may be on one or more recorders. DPA Resume Event on desktop->Recording system receives->resumes the audio and video recording which may be on one or more recorders. With these kinds of interruptions or changes in the data collection, the systems herein account for the changes in the matching of different channels constituting a single multimedia interaction.

When dealing with kiosks it may be possible to provide further validation of the identity of the individual using contactless pay technologies as these would be used to confirm the identity of the person in the kiosk and subsequently use this to cross check with a face on record, or in some scenarios drive enrolment. This system is implemented with multiple facets of biometric data that can be correlated—such as tagging, time stamps, metadata; consider other correlation points such as location data as a fraud check tool. Furthermore additional gateway side recording of video, audio, screen data may be implemented. When considering issues such as the Billing ANI, the Real ANI, the presentation ANI, and the various proxy algorithms in Video over IP recording there remains a question of which location is the best for tapping with recording hardware to implement algorithms such as metadata and audio.

In this regard, a system may include a monitoring server (1000) comprising a processor and a memory coupled to the processor, the memory storing a set of trigger condition data. A remote agent workstation (1071, 1078) comprising respective applications operating thereon is in data communication with the monitoring server over a network, wherein the monitoring server and the remote agent workstation are configured with respective computer implemented instructions to perform a method comprising the steps of (i) receiving, at the monitoring server and via the network, multimedia updates from the remote agent workstation, the multimedia updates corresponding to changes in workstation data processed by at least one of the applications on the remote agent workstation; (ii) identifying, at the monitoring server, the presence of a trigger condition from the multimedia updates, and upon identifying by the monitoring server that the trigger condition exists; (iii) controlling, with the monitoring server, data recording of audio data and on-screen data associated with the remote agent workstation; (iv) capturing, during the data recording, video imagery from the remote agent workstation; and (v) storing the audio data, on-screen data, and video imagery in a call records database. The trigger condition data includes facial recognition data for an agent at the remote agent workstation and the trigger condition comprises an agent identification. The trigger condition data comprises a voice signature for an agent at the remote agent workstation, and the system further comprising comparing the voice signature to the audio data for an agent identification. A system according to this embodiment analyzes the audio data or the video imagery for gender detection, race detection, physical body attributes, voice volume detection, voice frequency patterns, facial obscurities, health symptoms, skin aberrations, and exposed flesh conditions in regard to the agent. Another embodiment is triggered by detecting a document or a document content.

In one embodiment, a customer camera is also connected to a customer facing computer on the network such that a customer using the customer facing computer is within a customer camera field of view. A customer security camera, having a first geographical area within the customer security camera field of view is connected on the same network or across a link from a different network. An agent interaction camera is connected to the remote agent workstation and the network such that an agent using the remote agent workstation is within an agent interaction camera field of view.

An agent security camera is connected to the network and positioned to encompass an agent workspace and a second geographical area within the agent security camera field of view. The trigger condition data may include facial recognition data for a customer within the customer camera field of view or the customer security camera field of view and the trigger condition comprises a customer identification. The trigger condition data may also comprise a voice signature for a customer at the customer facing camera, and in this non-limiting embodiment, the system further comprises comparing the voice signature to customer audio data for a customer identification. The processing systems disclosed herein include software modules for analyzing customer audio data or customer video imagery for gender detection, race detection, voice accent detection, physical body attributes, voice volume detection, voice frequency patterns, facial obscurities, health symptoms, skin aberrations, and exposed flesh conditions in regard to the agent.

In one non-limiting embodiment, the customer camera and the customer security camera forward respective versions of both customer audio data and customer video data to a first private branch exchange in communication with the network, and the agent security camera and the agent interaction camera forward additional versions of both agent audio data and agent video data to a second private branch exchange in communication with the network. An archival recording apparatus is connected to the network, wherein each of the first and second private branch exchanges comprises local session border controllers and local load balancers that direct duplicate versions of the customer audio data, customer video data, agent interaction audio data, agent interaction video data, agent security audio data, and agent security video data to the archival recording apparatus.

The archival recording apparatus may be positioned in a data center connected to the network, and the data center comprises at least one analytics server configured to access the duplicate versions in the archival recording apparatus. The analytics server comprises at least one application that stitches portions of the duplicate versions of the customer audio data, customer video data, agent interaction audio data, agent interaction video data, agent security audio data, and agent security video data into a compilation version of a customer transaction. The analytics server identifies triggers from the duplicate versions, wherein the triggers direct computer implemented instructions from the analytics server to a customer facing computer and an agent facing computer connected to the network. The analytics server identifies a trigger in the form of either private video or private audio content and pauses recording. The instructions programmed in the analytics server, a load balancer, or a session border controller may include directives to off load processing functions to a graphics processor.

The embodiments of data recording systems and even real time analytics programs allow for development of a system for scoring an agent interacting with customers by electronic means. In one embodiment, a scoring module connected to a network processor may include an analytics server having a processor and a memory coupled to the processor, a remote agent workstation comprising respective applications operating thereon and in data communication with the analytics server over a network, a customer camera connected to a customer facing computer on the network such that a customer using the customer facing computer is within a customer camera field of view, an agent interaction camera connected to the remote agent workstation and the network such that an agent using the remote agent workstation is within an agent interaction camera field of view, wherein the analytics server, the remote agent workstation, and the customer facing computer are configured with respective memory storing computer implemented instructions to perform a method comprising the steps of:

(i) authenticating the agent at the remote agent workstation;

(ii) scoring the agent according to score parameters stored in the memory of the analytics server by comparing the score parameters to customer audio data, customer video data, agent interaction audio data, and agent interaction video data.

As discussed herein, the analytics server is configured to:

selectively gather screen captures of the at least one agent computer during the bi-directional communications and, in real time, parse a portion of the screen capture for analysis;

selectively gather video data generated at the at least one agent computer and, in real time, parse a portion of the video data for analysis;

selectively gather audio data generated at the at least one agent computer and in real time, parse a portion of the audio data for analysis. These features of the system allow the system to authenticate the agent by one or more of real time speech analytics performed on the portion of the audio data and biometric data gathered from the portion of the video data. Furthermore, the analytics server compares the score parameters to at least one of the portions of the agent video data sufficient to evaluate virtual eye contact between the agent and the customer.

In other embodiments, the system may incorporate a customer security camera connected to the network and having a first geographical area within the customer security camera field of view and an agent security camera connected to the network and positioned to encompass an agent workspace and a second geographical area within the agent security camera field of view, wherein the system is configured to:

(i) selectively gather screen captures of either the agent computer or the customer computer during the bi-directional communications and, in real time, parse a portion of the screen capture for analysis;

(i) selectively gather video data generated at the at least one agent computer or the customer computer and, in real time, parse a portion of the video data for analysis;

(iii) selectively gather audio data generated at either the agent computer or the customer computer and in real time, parse a portion of the audio data for analysis.

In order to ease the enrolment of both audio and faces in the biometrics and identity systems, if the person is already registered one characteristic then it can be used to speed the enrolment of the other. For example if I have a positive match of the voice biometric, then the face can be enrolled based on the contact and the successful voice authentication. Similarly the reverse is also true if the face matches that of the enrolled individual then the interaction can be used to enroll the person's voice. Use the enrollment data to check and see if real time data matches the historical data for this ID. If not, then define next actions. View the video recording allow document extraction, using character recognition type capabilities, all on the same camera, for example the customer maybe able to provide proof of 1D via this mechanism holding up their passport and drivers licenses etc.

Where the system knows information such as the customers social media identity it can use this information to cross check their face and even potentially enroll the customer from their picture in the social space. Indeed many social media applications do provide face API's and it may be that the recording system interfaces to this to provide assistance or services in the identification of individuals. Similar face comparison might exist from Instagram or linkedin profile pictures, the system with enroll, calibrate and refine its face recognition capability based on multiple sources, and will also use this to mitigate issues from the passage of time, for example the system may learn that the person has indeed grown a beard from their social pictures. The system may equally use social presence information to confirm location information, if for example it receives calls from someone abroad and yet can determine from their posted location information that they are not abroad this might help identify fraud. One may then consider a layered approach to verifying the image with intelligence tracking along and along that gradually grows into accuracy based on the social media source along with above discussed time stamp, meta data, video, audio, screen data quality, reproduction potential and the like.

The video medium may also be used to deliver announcements to the customer that has traditionally been delivered via audio; examples would include beeps if the call is being recorded. In this disclosure the recording system would invoke the display of the message to one or more parties on the video call that the call is being recorded.

Equally the system may simply present to the agent the picture of the customer on record, so that the agent can make their own determine if this is the correct person on the video link.

Equally the information about the customer involved in the call and other derived analytics such as emotion might be used to drive targeted video marketing material either during the agent conversation or just after.

Equally the information from the video stream may be used to drive detailed survey information after the call has ended by before the customer has left the conversation.

In real-time and post call recording within the recording system the system will have the ability to combine derived data events form the video stream such as face identity, emotion, eye-contact, disguise, with event form the audio stream such as voice biometrics, spoken words, language identification, this intern via the use of rules can be used to drive actions such as email, screen popups, 3^(rd) party system notifications. In addition the recording system will be able to take other meta-data captured by the system and apply this to the rules in order to further drive the actions. This ability to combine these events form different contact streams within the environment in both real and post process will be unique. The system may further use biometric and metadata event from external elements to drive elements such as enrolment.

For example:

Recording System Validates the face->Recording System Validates the voice->Recording system receives account information from a validated smart/automated touch or wireless transaction->Recording system delivers a low risk score event to the agent via desktop popup. Recording System receiving the Account ID->Recording System Validates the voice->Recording system determines that there is no face on record->Recording system enrolls the capture face in the system.

These events may arrive in any order and may result in one or more actions per call.

The systems described above include taking more samples of the voice, storing updated versions of the voice prints and iteratively learn which voice print is the best one to save that captures all the nuances in prior saved versions so that the voice print can be used for ID purposes without having to search a larger history of voice prints. Post processing issues might include real time data acquisition used to flag and pre-select certain video/audio/screen selection and then retroactive batch processing. For example, identify repeated calls and voices/images/data related to a call. Cross Channel Diagnostic algorithms allows for multi-media capture (email, chat, social media, audio, video, screen data, incorporating tags and analytic results into meta data that can be useful to hardware used in various systems (e.g., sending customers to the same agent as last time the customer called in or came to kiosk).

Security measures for archival systems may include encryption techniques at any point of the processes.

As used herein, all of the systems of this disclosure are amenable to the incorporation of automatic steps, such as automatic face, text, or voice recognition. The logic of the modules enacted herein is equipped to do multiple recordings simultaneously and use meta data logic and algorithms to associate the screen, video and audio together with the use of additional meta data streams, for example the audio and video will be associated by the ip addresses potentially of the data streams, whereas the screen capture might be associated by the logged-on user at the computer and associating this to the extension/agent id. The systems herein incorporate the use of applying additional meta data content to the recorded media streams to add context, increase the correlation and allow the application of advanced business rule logic in routing, applications and storage of said media streams. For example only recording specific video endpoints, only allowing application access based on identity information associated with the media streams, only archiving content from specific streams based on associated identity of line of business information for example. Generally there would be logic to associate and control the association of situational camera's along with the video interaction recordings of audio, video and screen we should ensure the use of this control server and any associated meta data that might be received from other sources is also covered. For example you might go into a mortgage meeting in a room, the conversation would be recorded on the agents PC/Phone and then the video associated from the security camera covering the room.

The designs of this disclosure ensure the association of one or more security cameras is covered for example as the customer makes their way to the eventual agent meeting and leave it, and this associate logic might be achieved by identifying piece of security footage with the matching face in it for example or other associated metadata. Instead of storing the imagery in the call records database, the system may be configured to store files on disk storage, the database usually has metadata that is used to find the content in the file storage. Media content even within the same call may be stored in different locations, i.e. audio, screen and video could all have different location and retention periods.

Generally, all embodiments described herein include mobile devices such as phones and tablets, from audio, screen, video, geolocation and metadata perspective. And any mix thereof, i.e. customer on a smart phone, and agent on a PC etc.

Associated to the quality monitoring we need a claim for a recording system with the ability to provide a real-time live feed to a monitoring supervisor of the video, audio and screen content on a agent, this basically provides the equivalent live monitor functionality we have today with the added complexity of delivering the video on in real-time with association to the audio and screen streams which may be coming from different recording/capture locations. These embodiments further ensure that real-time use of analytics i.e. identifying someone face straight away during the call and is able to provide alerts, impaction application logic or routing of the call. Of course, the embodiments described herein incorporate post interaction analytics allowing a user to review content by going back over calls looking for newly identified elements that maybe of interest i.e. a newly discovered person of interest.

Another element that is particularly useful in the methods, systems and apparatus of this disclosure is multi-factor identification, where at least one element from multiple data streams is used in real time or post process to verify or identify attributes of the people involved in the calls, for example the voice of the customer from the audio, the face of the customer from the video, will both be used to identify a customer and these two identities will be compared together to ensure they match, providing true multi-factor authentication.

FIGS. 10 and 11 illustrate example processes for proper archival purposes in regard to multimedia data interactions and communications. As discussed above, the monitoring server (1000) may include software to identify multimedia data triggers that correspond to protocols initiated for preparation in regard to archival and storage operations.

One operation that may be useful in the logic of control software for operation of storage and archival includes determination of tapping locations, discussed above. Factors that may come into account in determining a proper tap location for a particular kind of data (identified pursuant to multimedia data tags) may be tabulated as follows without limiting this disclosure to any one set-up or logical algorithm:

TABLE 1 TAP- TAP- TAP- TAP- Session Switch Automatic TAP- Network TAP- Border Port Call IP Trunk Gateway Controller Analyzer Distribution Analyzer (TAP_(NT)) (TAP_(GW)) (TAP_(SBC)) (TAP_(SPAN)) (TAP_(ACD)) (TAP_(IPA)) Direct Stream Yes Yes Yes Yes Yes Yes Recording Forking + No Yes Yes No Yes Yes Recording Duplication + No No Yes Yes No No Recording Decoding/ No Yes Yes No No No Reconstruction + Recording Filtering + No Yes Yes Yes Yes Yes Recording Selective No Yes Yes No No Yes Frame Recording Signaling Data No Yes Yes No No No Analysis + Recording Meta Data No No No Yes No Yes Analysis + Recording Control Plane No Yes Yes Yes No Yes Analysis + Recording Data Plane No No No No No Yes Analysis + Recording XML Data No No No Yes No Yes Anlaysis + Recording Incoming Data Yes No No No No No Only Back to Back No No No Yes No No Video Proxy Audio & No No No Yes No Yes Video Syncing Data Frame No Yes Yes No No No Tagging Time Stamp No Yes Yes Yes No No Insertion

At least one additional embodiment that may be gained via the discussion above includes a system wherein the session border controller is configured as an SIP proxy for incoming data. Also a system for analyzing multimedia data content over a network may include a customer camera connected to a customer facing computer on the network such that a customer using the customer facing computer is within a customer camera field of view; an agent interaction camera connected to an agent facing computer on the network such that an agent using the agent facing computer is within an agent interaction camera field of view; an agent security camera connected to the network and positioned to encompass an agent workspace within the agent security camera field of view; an archival recording apparatus connected to the network and comprising a recording processor and recording memory configured to receive respective incoming data streams of multimedia data from the customer camera, the agent interaction camera, and the agent security camera, wherein the recording apparatus stores an archive compilation of at least portions of the respective incoming data streams. The same system may further include a customer security camera having a first geographical area within the customer security camera field of view. The customer camera and the customer security camera forward respective versions of both customer audio data and customer video data to a first private branch exchange in communication with the network, and the agent security camera and the agent interaction camera forward additional versions of both agent audio data and agent video data to a second private branch exchange in communication with the network. Each of the first and second private branch exchanges comprises local session border controllers and local load balancers that direct duplicate versions of the customer audio data, customer video data, agent interaction audio data, agent interaction video data, agent security audio data, and agent security video data to the archival recording apparatus. The archival recording apparatus is positioned in a data center connected to the network and the data center comprises at least one analytics server configured to access the duplicate versions in the archival recording apparatus. An analytics server may be configured to utilize at least one application that stitches portions of the duplicate versions into a compilation version of a customer transaction. 

1. A recording system comprising: at least one agent computer configured to accommodate bi-directional communications over a network between the at least one agent computer and a remote computer, the at least one agent computer connected to a processor and memory configured with an archiving selection module; a first recording apparatus in data communication over the network with the at least one agent computer, the first recording apparatus configured to implement instructions received from the archiving selection module to: selectively gather screen shots of the at least one agent computer during the bi-directional communications and store the screen shots with a respective time stamp; selectively gather video data generated at the at least one agent computer and store the video data with a video time stamp; selectively gather audio data generated at the at least one agent computer and store the audio data with an audio time stamp.
 2. A system according to claim 1, wherein the archiving selection module comprises computer implemented commands stored therein to effect the selective gathering according to a randomizing rule, a line of business rule, or by locating a third party tag within the bi-directional communications.
 3. A system according to claim 1, further comprising an archival system connected to the network for storing the screen shots, the video data, and the audio data after assembling a consolidated communication according to the time stamps as adjusted for drift errors.
 4. A system according to claim 1, wherein the first recording apparatus is positioned in a first private branch exchange local to the at least one agent computer, the system further comprising a second recorder in data communication with a customer computer in a second private branch exchange, the second recorder selectively gathering remote audio, remote video, and remote screen shots from the customer computer according to corresponding instructions from the archiving selection module.
 5. A system according to claim 1, wherein the archiving selection module is stored in a data center between the at least one agent computer and the customer computer.
 6. A system according to claim 1, wherein the at least one agent computer is in communication with a load balancer comprising computer memory and a processor configured to parse the bi-directional communications into screen data, video data and audio data according to identification protocols accessible to the processor.
 7. A system according to claim 1, further comprising a respective portion of memory in the first recorder for audio data, video data, and screen shot data.
 8. A system according to claim 1, further comprising respective recorders for audio data, video data, and screen shot data.
 9. A system according to claim 8, further comprising an archival system connected to the network for storing the screen shots, the video data, and the audio data after assembling a consolidated communication according to the time stamps as adjusted for drift errors.
 10. A system according to claim 9, wherein the archival system comprises a consolidation module to pair audio data and screen shot data and store video data separately.
 11. A system according to claim 9, wherein the archival system operates according to rules based commands for down sampling for long term storage an incoming data stream according to content of audio data, video data, and screen shot data.
 12. A recording system comprising: at least one agent computer configured to accommodate bi-directional communications over a network between the at least one agent computer and at least one customer computer, wherein the bi-directional communications traverse a data center server; a plurality of recording apparatuses connected over the network to the data center server, the at least one agent computer and the at least one customer computer; a load balancer connecting the recording apparatuses to the at least one agent computer and the at least one customer computer and receiving data streams representing respective portions of the bi-directional communications, the load balancer directing the portions of the bi-directional communications to a selected recording apparatus for storing recordings of the portions to recording memory; a topology processor tracking a respective status of bi-directional communications between pairs of the at least one agent computer and at least one customer computer and storing topology states in a topology memory bank, wherein the topology states comprise, for respective portions of the bi-directional communications, a data stream origination address, a data stream endpoint address, and a time stamp; and an archival system receiving the recordings according to archival rules accessing the topology states.
 13. A recording system according to claim 12, wherein said topology states comprise time based records of the data streams originating from the agent computer or the customer computer.
 14. A recording system according to claim 12, further comprising computer implemented instructions within the archival rules to identify one computer as an agent computer or a customer computer for storing recording streams according to the respective data stream origination address, data stream endpoint address, and time stamp for the identified one computer.
 15. A recording system according to claim 12, further comprising computer implemented instructions stored in the archival rules instructing the topology processor and load balancer to identify a selected delta signal from a selected data stream originating from or received by the identified one computer.
 16. A system for scoring an agent interacting with customers by electronic means, comprising: an analytics server comprising a processor and a memory coupled to the processor; a remote agent workstation comprising respective applications operating thereon and in data communication with the analytics server over a network; a customer camera connected to a customer facing computer on the network such that a customer using the customer facing computer is within a customer camera field of view; an agent interaction camera connected to the remote agent workstation and the network such that an agent using the remote agent workstation is within an agent interaction camera field of view; wherein the analytics server, the remote agent workstation, and the customer facing computer are configured with respective memory storing computer implemented instructions to perform a method comprising the steps of: authenticating the agent at the remote agent workstation; scoring the agent according to score parameters stored in the memory of the analytics server by comparing the score parameters to customer audio data, customer video data, agent interaction audio data, and agent interaction video data.
 17. A system according to claim 16, wherein the analytics server is configured to: selectively gather screen shots of the at least one agent computer during the bi-directional communications and, in real time, parse a portion of the screen shot for analysis; selectively gather video data generated at the at least one agent computer and, in real time, parse a portion of the video data for analysis; selectively gather audio data generated at the at least one agent computer and in real time, parse a portion of the audio data for analysis.
 18. A system according to claim 16, configured to authenticate the agent by one or more of real time speech analytics performed on the portion of the audio data and biometric data gathered from the portion of the video data.
 19. A system according to claim 18, wherein the analytics server compares the score parameters to at least one of the portions of the agent video data sufficient to evaluate virtual eye contact between the agent and the customer.
 20. A system according to claim 18, further comprising: a customer security camera connected to the network and having a first geographical area within the customer security camera field of view; and an agent security camera connected to the network and positioned to encompass an agent workspace and a second geographical area within the agent security camera field of view, wherein the system is configured to: selectively gather screen shots of either the agent computer or the customer computer during the bi-directional communications and, in real time, parse a portion of the screen shot for analysis; selectively gather video data generated at the at least one agent computer or the customer computer and, in real time, parse a portion of the video data for analysis; selectively gather audio data generated at either the agent computer or the customer computer and in real time, parse a portion of the audio data for analysis. 